Multibody kinematics optimization with marker projection improves the accuracy of the humerus rotational kinematics

Multibody kinematics optimization with marker projection improves the accuracy of the humerus rotational kinematics

Markers put on the arm undergo large soft tissue artefact (STA). Using markers on the forearm, multibody kinematics optimization (MKO) helps improve the accuracy of the arm kinematics especially its longitudinal rotation. However deleterious effect of STA may persist and affect other segment estimat...

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Bibliographic Details
Published in:Journal of biomechanics Vol. 62; pp. 117 - 123
Main Authors: Begon, Mickaël, Bélaise, Colombe, Naaim, Alexandre, Lundberg, Arne, Chèze, Laurence
Format: Journal Article
Language:English
Published: United States Elsevier Ltd 06-09-2017
Elsevier Limited
Elsevier
Subjects:
Accuracy
Activities of Daily Living
Adult
Algorithms
Biomechanical Phenomena
Biomechanics
Cuffs
Engineering Sciences
Forearm
Forecasting
Humans
Humerus
Humerus - physiology
Kinematics
Male
Marker projection algorithm
Markers
Mathematical analysis
Mechanics
Medicin och hälsovetenskap
Movement - physiology
Multibody kinematics optimization
Optimization
Parameter estimation
Posture
Range of Motion, Articular
Rotation
Scapula
Sensors
Shoulder
Skin
Sports
Upper Extremity - physiology
Upper-limb
Upper-limb
Multibody kinematics optimization
Marker projection algorithm
CINEMATIQUE
UPPER-LIMB
MARKER PROJECTION ALGORITHM
MULTIBODY KINEMATICS OPTIMIZATION
BIOMECANIQUE
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Description
Summary:Markers put on the arm undergo large soft tissue artefact (STA). Using markers on the forearm, multibody kinematics optimization (MKO) helps improve the accuracy of the arm kinematics especially its longitudinal rotation. However deleterious effect of STA may persist and affect other segment estimate. The objective was to present an innovative multibody kinematics optimization algorithm with projection of markers onto a requested axis of the local system of coordinates, to cancel their deleterious effect on this degree-of-freedom. Four subjects equipped with markers put on intracortical pins inserted into the humerus, on skin (scapula, arm and forearm) and subsequently on rigid cuffs (arm and forearm) performed analytic, daily-living, sports and range-of-motion tasks. Scapulohumeral kinematics was estimated using 1) pin markers (reference), 2) single-body optimization, 3) MKO, 4) MKO with projection of all arm markers and 5) MKO with projection of a selection of arm markers. Approaches 2–4 were applied to markers put on the skin and the cuff. The main findings were that multibody kinematics optimization improved the accuracy of 40–50% and the projection algorithm added an extra 20% when applied to cuff markers or a selection of skin markers (all but the medial epicondyle). Therefore, the projection algorithm performed better than multibody and single-body optimizations, especially when using markers put on a cuff. Error of humerus orientation was reduced by half to finally be less than 5°. To conclude, this innovative algorithm is a promising approach for estimating accurate upper-limb kinematics.
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ISSN:0021-9290
1873-2380
1873-2380
DOI:10.1016/j.jbiomech.2016.09.046